WO2020036807A1 - Sondage de canal dans des réseaux mimo massifs hybrides - Google Patents

Sondage de canal dans des réseaux mimo massifs hybrides Download PDF

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Publication number
WO2020036807A1
WO2020036807A1 PCT/US2019/045768 US2019045768W WO2020036807A1 WO 2020036807 A1 WO2020036807 A1 WO 2020036807A1 US 2019045768 W US2019045768 W US 2019045768W WO 2020036807 A1 WO2020036807 A1 WO 2020036807A1
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sub
domain
terminal
antenna
antennas
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PCT/US2019/045768
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Sayed Reza Monir Vaghefi
Dilip BETHANABHOTLA
Mihai Banu
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Blue Danube Systems, Inc.
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Publication of WO2020036807A1 publication Critical patent/WO2020036807A1/fr

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/0413MIMO systems
    • H04B7/0456Selection of precoding matrices or codebooks, e.g. using matrices antenna weighting
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/0413MIMO systems
    • H04B7/0417Feedback systems
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/0413MIMO systems
    • H04B7/0456Selection of precoding matrices or codebooks, e.g. using matrices antenna weighting
    • H04B7/0478Special codebook structures directed to feedback optimisation
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/0413MIMO systems
    • H04B7/0456Selection of precoding matrices or codebooks, e.g. using matrices antenna weighting
    • H04B7/0478Special codebook structures directed to feedback optimisation
    • H04B7/0479Special codebook structures directed to feedback optimisation for multi-dimensional arrays, e.g. horizontal or vertical pre-distortion matrix index [PMI]
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/06Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
    • H04B7/0686Hybrid systems, i.e. switching and simultaneous transmission
    • H04B7/0695Hybrid systems, i.e. switching and simultaneous transmission using beam selection
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L25/00Baseband systems
    • H04L25/02Details ; arrangements for supplying electrical power along data transmission lines
    • H04L25/0202Channel estimation
    • H04L25/0224Channel estimation using sounding signals
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L25/00Baseband systems
    • H04L25/02Details ; arrangements for supplying electrical power along data transmission lines
    • H04L25/0202Channel estimation
    • H04L25/0224Channel estimation using sounding signals
    • H04L25/0226Channel estimation using sounding signals sounding signals per se
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/06Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
    • H04B7/0613Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station using simultaneous transmission
    • H04B7/0615Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station using simultaneous transmission of weighted versions of same signal
    • H04B7/0619Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station using simultaneous transmission of weighted versions of same signal using feedback from receiving side
    • H04B7/0621Feedback content
    • H04B7/063Parameters other than those covered in groups H04B7/0623 - H04B7/0634, e.g. channel matrix rank or transmit mode selection

Definitions

  • the present invention is directed to methods employed in massive MIMO arrays and, more particularly, to methods using a dynamically configurable, active antenna array system (AAS) to sound channels to acquire channel state information.
  • AAS active antenna array system
  • MIMO is a wireless communication method that increases the capacity and quality of a wireless link by using a plurality of transmit and receive antennas to exploit multipath propagation.
  • MIMO is used in various wireless technology standards.
  • the 3rd Generation Partnership Project (3GPP) is one example of a global effort to determine the policy and strategy of several standards concerning wireless data communication technologies for mobile systems.
  • 3GPP utilizes MIMO technologies in 4G standards such as Long-Term Evolution (LTE), LTE- advanced and 5G standard such as New Radio (NR).
  • LTE Long-Term Evolution
  • NR New Radio
  • a massive MIMO system uses a very large number of transmit antennas (e.g., hundreds or thousands) to simultaneously send and receive multiple data layers to and from multiple receivers.
  • MIMO systems depend on multipath signals to establish high data rate wireless data transmission.
  • the MIMO system implements a Downlink that conveys signals from transmission points such as a Base Station (BS), referred to as eNodeB in LTE and gNodeB in NR, to User Equipment (UE) terminals and an Uplink that conveys signals from UEs to BSs.
  • BS Base Station
  • UE User Equipment
  • the terminals can be cellphones, smartphones, tablets, or any devices with wireless capability communicating with the base station.
  • the base station by utilizing the massive MIMO technology, has the capability to form a plurality of radio links with each of a plurality of terminals located in a horizontal and vertical space surrounding this base station.
  • the horizontal space can, for example, be segregated into three 120° segments surrounding the base station with at least one MIMO antenna per segment or domain.
  • the vertical space can be one contiguous segment. Other segregations in the horizontal, as well as vertical, are possible.
  • DSP digital signal processing
  • DSP digital signal processing
  • the transmitter/receiver units coupled to one or more antennas in the antenna array.
  • the one or more antennas driven by the ports or transmitters combine the emitted signals from the antenna array such that particular directions of the emitted electromagnetic radiation constructively interfere while other directions destructively interfere thereby forming a directed radiation beam.
  • This directional aspect is referred to as beamforming or spatial filtering.
  • the overall coverage of the beamforming of an antenna array is dependent on the individual antenna domain and the number of antennas driven by a port. If each antenna in the antenna array is driven by a separate port, the beams that are formed have a maximum angular spread or coverage over its domain. Larger antenna arrays are more desirable to increase array gain and multiplexing gain. However, a large antenna array would be costly if a port was used for each antenna. The number of ports implemented in the larger antenna array can be decreased. For example, the array can be partitioned into a plurality of sub-arrays made up of sub-sets of antennas, each driven by a corresponding one of the ports.
  • One benefit of connecting each port to multiple antennas is an improvement in the power efficiency of the antenna array. Another benefit is a reduction in cost, since fewer ports requires fewer hardware components. On the other hand, reducing the number of ports reduces the maximum scan angle of the beams formed by the antenna array over its domain. Another downside of reducing the port count is the generation of sidelobes or spurs formed in the beam generated by the antenna array. Since each port drives multiple antenna elements, those antenna elements are controlled with the same digital weights, thereby reducing the resolution of the antenna array pattern and creating unwanted beam sidelobes. Sidelobes in an antenna array beam pattern in turn reduce the capacity performance of the MIMO system.
  • the base station strives to boost the capacity experienced by all the UEs in its coverage through various techniques such as spatial multiplexing using multiple antennas and precoding data streams to eliminate inter-stream interference.
  • Precoding is a signal processing operation that is performed on the data streams to reduce interference among transmissions to multiple UEs and maximize the SINR at each of the individual UEs.
  • channel sounding is used to estimate the channel characteristics of multipath signals.
  • the BS typically relies on channel state information (CSI) obtained either from feedback given by the UEs based on their own downlink channel estimation performed with the help of downlink pilot signals transmitted from the BS antennas or from uplink pilot signals transmitted by the UEs (under TDD reciprocity
  • the BS would transmit M downlink pilot signals corresponding to the M antennas.
  • the pilot signals are also referred to as CSI reference signals, called channel state information- reference signals (CSI-RS) in Release 10 and beyond 3GPP.
  • CSI-RS channel state information- reference signals
  • the pilots are specific sequences of signals known to both the base station and the terminal.
  • the terminals after receiving the pilots, use them pilots to determine the characteristics of the channel and feed back that information to the BS.
  • the pilots help to determine the direction, the quality, and the number of independent paths formed in the channel. These are correspondingly represented by, the Precoding Matrix Indicator (PMI), the Channel Quality Indicator (CQI), and the Rank Indicator (RI) and are reported back to the base station from each terminal.
  • the base station uses this information to transmit a more reliable signal and transfer higher data rate to each terminal. More specifically, the BS selects the precoding matrix identified by the returned PMI and applies that precoding matrix to the layers to generate port signals.
  • the BS runs signal processing algorithms, such as zero forcing, on these estimates to generate the precoding vectors.
  • the data streams that are precoded with these vectors are transmitted to the UEs in such a way that each UE receives its own stream without interference from other streams.
  • the embodiments described herein employ a method that acquires CSI in a system with a fewer number of digital ports by using dynamic subarray mapping thereby reducing both signaling overhead and implementation cost.
  • the AAS can shape or focus radio frequency (RF) energy in the downlink, and receive sensitivity in the uplink, by adjusting the magnitudes and the phase shifts of the transmit and receive signals at its plurality of antenna elements.
  • DL downlink
  • UL uplink
  • RX receive
  • Embodiments of this disclosure include methods and systems to improve channel sounding measurements and capacity of massive MIMO antennas having a reduced port count.
  • Reference signals sent from the MIMO antenna are used to sound the channel.
  • the horizontal and vertical angular spreads (HVAS) of the PMIs can cover the desired domain of the base station.
  • HVAS horizontal and vertical angular spreads
  • the PMIs can experience a reduced HVAS, which causes a reduction in the coverage of the desired domain. Examples exist where the HVAS may be reduced by a factor of two or more in either the horizontal and/or the vertical directions causing some of the sub-sectors of the desired domain to receive an attenuated signal or no signal at all.
  • the terminals (user equipment) in these sub-sectors of the desired domain of the base station may not return the accurate channel state information (CSI) feedback information to the base station.
  • CSI channel state information
  • phase shifter coupled to each antenna of the reduced port MIMO to increase the array’s coverage over the desired domain.
  • phase shifters can be controlled to electrically steer all of the antenna’s output beams independently in any direction desired in a matter of milliseconds (ms) or less.
  • the analog phase shifters can also be used to steer all of the antenna’s output beams in the same direction.
  • a resource mapping and precoding block generates control signals, in a first time interval, to digitally control the analog phase shifters to steer all the reference CSI-RS beams together to cover a first sub-sector of the desired base station’s domain.
  • all the reference CSI-RS beams together steer to cover a second sub-sector.
  • each of the pluralities of sub-sector within the desired base station’s domain is covered until the entire desired domain of the base station has been fully covered.
  • Another embodiment of this disclosure uses the resource mapping and precoding block to combine the PMIs returned from the CSI-RS measurements with the digital control values applied to the analog phase shifters for each of the pluralities of sub-sectors.
  • the combination creates new set of digital control values for the analog phase shifters.
  • These new digital control values are the values necessary to adjust the weights applied by analog phase shifters to steer the beams generated by the sub-arrays in the desired directions, i.e., the direction of the terminal with which the base station will be communicating.
  • the combination of the PMI value with the initial digital value provides a single digital value which is applied to the analog phase shifters to direct the beam in the desired direction, e.g.
  • This step of combining the PMIs with the digital control values that are applied to the analog phase shifters to produce a new set of digital control values for the analog phase shifters (and which eliminates the need for beam steering via the precoding matrices) removes the distortion of the side-lobes that occurs in a reduced port antenna system. Since each port is connected to multiple antennas, the combination of the multiple antennas driven by a single port creates an effective antenna that has spatial characteristics different than the placement of the individual antennas. The PMI value does not compensate for the new spatial characteristics of this effective antenna. However, the new digital value which combines the PMI value with the initial digital control value does compensate for the“effective antenna” effect.
  • the single digital control weight is applied to the analog phase shifters to form “analog” control values.
  • The“analog” control values steer the analog phase shifters for each of the pluralities of sub-sectors allowing the channel to carry data to the terminal within the domain of the base station in a substantially un-distorted (free of unwanted side-lobes) channel
  • the invention features a method involving a MIMO
  • the communications system including a phased array antenna for establishing communication with a terminal located within a domain covered by the MIMO communications system.
  • the method includes: defining a plurality of sub-domains within the domain; for each sub-domain, defining a corresponding set of analog phase weights to be applied to the phased array antenna for directing beams towards that sub-domain; in succession, selecting each sub-domain among the plurality of sub-domains and for each selected sub-domain: (a) applying the set of analog phase weights for that selected sub-domain to the phased array antenna; (b) performing channel sounding with the terminal while that sub-domain is selected; and (c) receiving feedback from the terminal for that selected sub-domain; and after selecting all sub-domains of the of plurality of sub-domains and from the feedback received from the terminal, identifying among the plurality of sub-domains, a best sub-domain and identifying a best precoding matrix that in combination with the best sub- domain provides a best communication channel for the terminal.
  • the method also includes using the best communication channel to carry out data communication with the terminal.
  • Using the best communication channel to carry out data communication with the terminal involves employing the identified precoding matrix and applying the set of analog phase weights for the identified best sub-domain to the phased array antenna to direct beams towards the identified best sub-domain.
  • using the best communication channel to carry out data communication with the terminal comprises deriving from the identified precoding matrix and the set of analog phase weights for the identified best sub-domain a revised set of analog phase weights and applying the revised set of analog phase weights to the phased array antenna.
  • using the best communication channel to carry out data communication with the terminal does not involve using the identified (or any) precoding matrix to perform any beam steering.
  • Performing channel sounding with the terminal while a sub-domain is selected involves sending reference signals to the terminal. It might involve non-precoded reference signal transmission (e.g. Class-A transmission) or it might involve precoded reference signal transmission (e.g. Class-B transmission).
  • the feedback from the terminal includes a Precoding Matrix Indicator (PMI) and possibly a Channel Quality Indicator (CQI).
  • PMI Precoding Matrix Indicator
  • CQI Channel Quality Indicator
  • Fig. 1 illustrates a table of a number of CSI-RS antenna ports determined by a codebook configuration.
  • Fig. 2 depicts the product of the ports multiplied by the codebook size per first and second dimension.
  • Fig. 3 shows the Class-A non-precoded CSI-RS transmission system with the base station and several terminal devices.
  • Fig. 4 depicts the Class-B beamformed CSI-RS transmission system with the base station and several terminal devices.
  • Fig. 5 illustrates the Hybrid CSI method using utilizing both the combination of coarse Class-A and the beamformed Class-B.
  • Fig. 6 illustrates the angular spread of electromagnetic radiation in delta (Q) and phi (f) for two different Ni and N 2 product values.
  • Fig. 7A-B shows two different partitions (32T32R and 8T8R) of horizontal and vertical port values for the same antenna array.
  • Fig. 8 depicts a block level system description for the base station of the conventional 32T32R configuration.
  • Fig. 9 shows the beams patterns in the horizontal and vertical planes for the conventional 32T32R configuration.
  • Fig. 10 depicts a block level system description for the base station of the conventional 8T8R configuration.
  • Fig. 11 depicts the beams patterns in the horizontal and vertical planes for the conventional 8T8R configuration.
  • Figs. 12A and 12B show a block level representation of an embodiment of a modified 8T8R configuration with a digital bus for analog beam adjustment.
  • Fig. 13 depicts the beams patterns in the horizontal and vertical planes for one embodiment of the modified 8T8R configuration with analog beam adjustment for a first and second time interval.
  • Fig. 14 depicts the beams patterns in the horizontal and vertical planes for one embodiment of the modified 8T8R configuration with analog beam adjustment for a third and fourth time.
  • Fig. 15 shows the angular spread of the four beam patterns corresponding to the first, second, third, and fourth time intervals.
  • Fig. 16 depicts a flow chart presenting the process of selecting and applying the codebook weight values to an antenna array.
  • Fig. 17 shows a flow chart to remove the distortion in the beam pattern due to the analog beamformer.
  • Fig. 18 depicts a distortion and removal of distortion in both the horizontal and vertical beam patterns for the conventional 8T8R, conventional 32T32R and the modified 8T8R methods.
  • Fig. 19 depicts table showing the performance values of one embodiment of the modified 8T8R system in comparison to the conventional 8T8R and conventional 32T32R systems (the conventional 8T8R system serving as reference).
  • Fig. 1 presents a table 1-1 of codebook configurations and port count for an antenna array mapping provided by 3GPP for Release 13 and beyond.
  • This codebook is a formal
  • the left column of the table in Fig. 1 presents the number of antenna ports P (or CSI-RS ports), ranging over values of ⁇ 8, 12, 16, 20, 24, 28, and 32 ⁇ .
  • the next column (Ni, N 2 ) shows several possible combinations of a first dimension (Ni) and second dimension (N 2 ) per polarization for each port P.
  • The“2” corresponds to the two polarities of the antenna, each orthogonal to the other (i.e., horizontal and vertical, as one example).
  • the next column presents the corresponding spatial over-sampling rates (Oi, 0 2 ) for dimensions (Ni, N 2 ) for each port P.
  • the final column indicates the standard 3GPP release number for the different number of ports.
  • Fig. 2 illustrates the total number of beams over the two dimensions 2-1.
  • the four polarization 0°, 90°, 180°, and 270° rotations are assigned to each beam providing a total of 1024 PMI’s for the 8T8R case.
  • This technique can be extended to two or more data layers where a data layer is an independent data stream.
  • Fig. 3 illustrates the non-precoded (non-beamformed) CSI-RS transmission known as Class- A.
  • the base station is not initially aware of the channel condition or the location of the one or more terminals 3-2 in its domain.
  • the base station through antenna 3-1 sends a CSI-RS from each antenna port to all of the terminals in its domain. Based on the received CSI-RS, each terminal then estimates the channel state information and selects a suitable precoding weight from a predetermined set of candidates (Codebook). The terminal sends back the selected index as a PMI (Precoding Matrix Indicator).
  • PMI Precoding Matrix Indicator
  • CSI feedback information also includes the RI (Rank Indicator), which indicates the number of transmission streams, and a CQI (Channel Quality Indicator) that determines the required modulation and coding scheme. This feedback information from the terminal to the base station is sent wirelessly and closes the loop of the base station sending user data to the terminals.
  • Fig. 4 illustrates the precoded (beamformed) CSI-RS transmission known as Class-B.
  • the base station sends multiple beamformed CSI-RS s to its domain.
  • the terminal selects one of the beamformed CSI-RSs and returns its CSI-RS Resource Index (CRI) along with the CQI to the base station. If the terminal is scheduled with more than one layer of data, the terminal also reports the PMI and RI. As before, this feedback information from the terminal to the base station completes the loop of the base station sending data to the terminal.
  • CRI CSI-RS Resource Index
  • 3GPP also supports hybrid CSI process technique where a combination of Class-A and Class-B processes is used.
  • CSI acquisition is performed in two stages.
  • the terminal uses a Class-A technique to report a coarse direction, where only one beam (5-1) within a group of four beams is reported.
  • the base station In the second stage, the base station generates 4 beamformed CSI-RSs around the reported direction in the first stage and then the terminal reports the best beam out of the 4 beamformed CSIs.
  • the main idea of a hybrid technique is to reduce the complexity of terminal CSI reporting.
  • Fig. 6 shows a graphical representation of a base station located at a given height (h) in the z-direction with its electromagnetic radiation covering a region of a spherical surface surrounding the base station.
  • the first rectangular region 6-1 specified by the dotted rectangle is proportional to the (first dimension times the second dimension) product of /V x N- while the larger solid lined rectangle 6-2 is proportional to the product of iV- X L ⁇ , where the second product is greater than the first product.
  • the product of the two dimensions of the port values also increases, and correspondingly the covered area increases as well.
  • the rectangular areas are an approximation to the actual outlined shaped areas of the plurality of beams.
  • the vertical angular changes are specified by the symbol Q while the horizontal angular changes are specified by the symbol f.
  • Fig. 7 A and Fig. 7B Two physically identical MIMO antenna arrays (number of antennas and placement of antenna elements) but partitioned into groups differently are depicted in Fig. 7 A and Fig. 7B.
  • Both antenna arrays have a first set of 48 antennas 7-1 oriented normally (first polarized) and a second set of 48 antennas 7-2 oriented orthogonal (second polarized) to the first set.
  • the array of Fig. 7a is a 32T32R (4, 4, 8, 4) system that is formed by grouping sets of three antennas within the dotted rectangles, for example, 7-3, 7-4, 7-5 and 7-6. This grouping causes the 32T32R system to have a first dimension (Ni) of 4 and a second dimension (N 2 ) of 4 for a total of 16 ports per polarization.
  • a first radio frequency (RF) chain (or port) couples to three of the normal antennas, oriented in a first direction, and a second RF chain (or port) couples to the
  • the 32T32R as depicted in Fig. 7A has 32 ports (T1-T32): 16 ports for the first polarized antennas and 16 ports for the second polarized antennas.
  • the 8T8R system depicted in Fig. 7B has the antennas in the array partitioned into sets of twelve antenna elements 7-10, 7-11, 7-12 and 7-13 (also referred to as sub-arrays).
  • This grouping causes the 8T8R system to have a first dimension (Ni) of 2 and a second dimension (N 2 ) of 2 for a total of 4 ports.
  • a first RF chain couples to twelve first polarized antennas and a second RF chain couples to the corresponding twelve second polarized antennas within each dotted rectangle.
  • the 8T8R has 8 ports (T1-T8): 4 ports for the first polarized antennas and 4 ports for the second polarized antennas.
  • the effective antenna is at a location within the partitions of the three antennas that corresponds to the center of the partition.
  • the center of this set of three antennas is the location 7-7 corresponding to the effective antenna for the set of the three antennas 7-4.
  • the center of this set of three antennas is the location 7-8 corresponding to the effective antenna for the set of the three antennas 7-5
  • the center of this set of three antennas is the location 7-9 corresponding to the effective antenna for the set of the three antennas 7-6.
  • the spacing between antennas in the antenna array is a distance G. That is, the horizontal distance between two adjacent antennas is G and that the vertical distance between two adjacent antennas is also G.
  • the effective antenna distance may be the same or larger.
  • the horizontal effective antenna distance between the location 7-7 of the set of the three antennas 7-4 and the location 7- 8 of the set of the three antennas 7-5 is the distance G.
  • the vertical effective antenna distance between the location 7-8 of the set of the three antennas 7-5 and the location 7-9 of the set of the three antennas 7-6 is the distance 3G.
  • the vertical effective antenna distance is three times greater than the horizontal effective antenna distance.
  • the horizontal effective distance being the same as the spacing between antennas in the antenna array.
  • the effective antenna is at a location within the partitions of the twelve antennas which corresponds to the center of the partition.
  • the center of this set of twelve antennas is the location 7-14 corresponding to the effective antenna location for the set of the twelve antennas 7-10.
  • the center of this set of twelve antennas is the location 7-15 corresponding to the effective antenna for the set of the twelve antennas 7-11
  • the center of this set of twelve antennas is the location 7-16 corresponding to the effective antenna for the set of the twelve antennas 7-12
  • the center of this set of twelve antennas is the location 7-17 corresponding to the effective antenna for the set of the twelve antennas 7-13.
  • the spacing between antennas in the antenna array is a distance G. That is, the horizontal distance between two adjacent antennas is G and that the vertical distance between two adjacent antennas is also G.
  • the effective antenna distance may be the same or larger.
  • the horizontal effective antenna distance between the location 7-14 of the set of the twelve antennas 7-10 and the location 7-15 of the set of the twelve antennas 7-11 is the distance 2G.
  • the vertical effective antenna distance between the location 7-15 of the set of the twelve antennas 7-11 and the location 7-17 of the set of the twelve antennas 7-13 is the distance 6G.
  • the vertical effective antenna distance is three times greater than the horizontal effective antenna distance.
  • the horizontal effective distance being twice the spacing between antennas in the antenna array.
  • a single antenna element in an array has a specific pattern. If a port is connected to multiple antenna elements, that generates an“effective element pattern” which is different from that produced by the single antenna element. For example, the overall scan angle for the multiple connected antenna elements is reduced and sidelobes are typically introduced. In addition, the unequal spacing of the antenna element in the horizontal and vertical direction of the antenna array also contributes to unwanted sidelobes.
  • FIG. 8 A block diagram of a conventional 32T32R (4, 4, 8, 4) system is illustrated in Fig. 8.
  • RMP resource mapping and precoding
  • Each port drives an RF chain 8-2 which implements various functions such as DAC (digital to analog conversion, up-conversion from IF Intermediate Frequency) to RF (Radio Frequency), and filtering, to name a few.
  • Each RF chain drives a l-to-3 sp Utter 8-3 coupled to three antennas 8-4.
  • the splitters 8-3 are basically corporate feeds (or their equivalent) for sending the same signal to each output of the splitter.
  • the antennas radiate their pattern into their corresponding domain surrounding the base station. Because of antenna orthogonality, 16 ports drive a total of 48 normal antennas while the remaining 16 ports drive a total of 48 orthogonal antennas.
  • the CSI feedback information from the one or more terminals based on the reference signals is sent back to the base station.
  • the feedback is used to beamform the data from the 96 antennas of the MIMO antenna array to the terminals through the application of the identified corresponding precoding matrix.
  • Fig. 9 illustrates the overall f and Q angular spread of the beams generated by the conventional 32T32R (4, 4, 8, 4) system in the horizontal and vertical planes, respectively.
  • the horizontal beams spread +/- 60° which cover 1/3 of the horizontal region (120°) around a base station, if the base station is partitioned into three equal domains.
  • these beams can be steered in the vertical direction over a range of +/- 11° within the vertical plane of the domain.
  • This domain substantially corresponds to the region 6-2 (see Fig. 6).
  • the codebook of the 32T32R (4, 4, 8, 4) antenna system contains up to 512 different beam directions over its entire angular spread of +/- 60° and +/- 11°. The maximum scan angle or angular spread depends on the antenna element pattern, the antenna element spacing, and the number of antennas driven by each port.
  • FIG. 10 A block diagram of a conventional 8T8R (2, 2, 8, 8) system is illustrated in Fig. 10.
  • Data to support 8 layers is coupled to the resource mapping and precoding block lO-lwhich generates 8 ports, Port 1 to Port 8, carrying the reference or/and data signals.
  • the system uses Class- A, Class-B, or Hybrid CSI processes and the block 10-1 also includes additional processing capabilities and control signals (not illustrated) to perform channel sounding and other processes required to operate a base station.
  • Each port drives an RF chain 10-2.
  • Each RF chain 10-2 drives a l-to-l2 splitter 10-3 which is then coupled to twelve antennas 10-4. Because of antenna orthogonality, 4 ports drive a total of 48 normal antennas; while the remaining 4 ports drive a total of 48 orthogonal antennas.
  • the CSI feedback sent from the terminal to the base station is based on the reference signals that the terminals received from the base station.
  • the CSI feedback which identifies the appropriate precoding matrix is used to beamform the data from the 96 antennas of the antenna array to the terminals that are in the domain of the base station.
  • This system operates similar to the system illustrated by Figs. 7B and 8 in which that the number of ports has been reduced by a factor of 4 (i.e., 1 ⁇ 4) while the grouping of the antennas has been increased by a factor of 4 (i.e., each port drives 12 antennas instead of 3).
  • the reduction in the number of ports affects the characteristics of the maximum angular spread of the beams that is achievable by the fixed array, as will be illustrated in the Fig. 11.
  • FIG. 11 illustrates the overall f and Q angular spread of the beams generated for the conventional 8T8R (2, 2, 8, 8) system in the horizontal and vertical planes, respectively.
  • the horizontal beams spread +/- 30° which cover 1/6 of the horizontal region (60°) around the base station.
  • these beams can be steered in the vertical direction of +/- 5.5° from the horizontal plane.
  • This domain substantially corresponds to the smaller region 6-1 (see Fig. 6).
  • the codebook for the 8T8R (2, 2, 8, 8) antenna system contains up to 256 beam directions over its entire angular spread.
  • the angular spread of the 8T8R (2, 2, 8, 8) antenna system has been reduced by approximately half in both the horizontal (from +/- 60° to +/- 30°) and vertical (from +/- 11° to +/- 5.5°) directions when compared to the 32T32R (4, 4, 8, 4) system.
  • the 8T8R (2, 2, 8, 8) antenna system attempts to perform the Class- A, Class-B, or Hybrid CSI processes, only 1 ⁇ 4 of the (1 ⁇ 2 of the horizontal times 1 ⁇ 2 of the vertical) angular spread is covered.
  • reducing the port count from 32 (in the32T32R antenna system) to a port count of 8 (in the 8T8R antenna system) causes a reduction in the angular spread by 1 ⁇ 2 in each of the horizontal and vertical directions.
  • Fig. 12A illustrates a block diagram of an embodiment of a modified 8T8R system that overcomes the problems associated with reducing the number of ports and which addresses the smaller angular spread associated with a conventional 8T8R antenna system.
  • the modified 8T8R system employs an active antenna array system that is capable of connecting each beam signal for a given polarity to each and every antenna element of that polarity and to independently control the analog phase shifts and analog gains applied to each signal that is delivered to an antenna element.
  • a resource mapping and precoding (RMP) block 12-1 receives 8 layers and generates eight ports, Port 1 to Port 8, therefrom. The eight ports carry the reference or data signals.
  • RMP resource mapping and precoding
  • the splitter block l2-3a operates on each of the port signals and for each port signal outputs 48 signals, each for a different one of the 48 antenna elements.
  • the remaining four ports, namely Port 5 to Port 8 are coupled through another set of corresponding conversion bocks 12-2 to a second splitter block l2-3b which, in turn, distributes those signals to the 48 orthogonal antenna elements.
  • the splitter block l2-3b operates on each of the port signals and for each port signal outputs 48 identical signals, each for a different one of the 48 orthogonal antenna elements.
  • the splitter block l2-3a is capable of outputting 192 signals, four signals for each of the 48 antennas
  • the conversion blocks 12-2 which are part of the previously referred to RF chains for each port signal, each implement various functions such as DAC (digital to analog conversion, up-conversion from IF (Intermediate Frequency) to RF (Radio Frequency), and filtering, etc.
  • the 384 signals from the splitters l2-3a and l2-3b pass to a dynamic software controlled analog beamformer block 12-4 which outputs 96 drive signals, one for each of the 96 antenna elements 12-5.
  • the analog beamformer block 12-4 applies analog phase shifts and magnitude weights to each of the 382 signals received by the beamformer block, combines the phase and amplitude weighted signals appropriately, and provides the combined signals to corresponding power amplifiers for each of the 96 antennas l2-5a and the 96 antennas l2-5b. Because of the high number of signal paths through the splitters l2-3a and l2-3b and through the analog beamformer block 12-4, it is not possible to show these signal paths in Fig. 12 A.
  • Fig. 12B illustrates an embodiment in which two port RF signals (Port 1 and Port 2) are delivered to four antenna elements 13-1.
  • the splitter block 13- 2 distributes the Port 1 signal to four output lines l3-3a, one for each of the four antennas 13-1; and it distributes the Port 2 signal to four different output lines l3-3b, one for each of the four antennas 13-1.
  • Those output signals from the splitters 13-2 are each processed by a dynamic software controlled analog beamformer 13-4.
  • Each signal passes through a corresponding phase/amplitude adjustment block 13-5 in the analog beamformer 13-4.
  • Each phase/amplitude adjustment block 13-5 includes a digitally controlled, phase shifter 13-6 and a digitally controlled, programmable gain amplifier (PGA) 13-7.
  • PGA programmable gain amplifier
  • a digitally controlled phase shift and gain to its corresponding input signals.
  • a signal combiner 13-8 before each antenna element which sums the phase and amplitude adjusted Port 1 and Port 2 signals and supplies that combined signal to a power amplifier (PA) 13-9 driving a corresponding antenna 13-1.
  • PA power amplifier
  • the arrangement enables one to generate through the array of antennas 13-1 two independently steerable and independently shaped transmit beams, one for the Port 1 signal and the other for the Port 2 signal.
  • the system shown in Fig. 12A operates in the same way, except that there are eight Port signals instead of two and 98 antenna elements in the array instead of four (48 with one polarization and 48 with an orthogonal polarization).
  • an analog beamformer control section 12-7 located in the resource mapping and precoding block 12-1 generates digital signals for controlling the phase shifters and PGAs in the analog beamformer 12-4.
  • Two digital control busses 12-8 and 12-9 connect the analog beamformer control section 12-7 to control the analog beamformer 12-4.
  • the digital control signals sent over those control buses set the analog phases and gains applied by the digitally controlled, phase shifters 13-6 and the digitally controlled, programmable gain amplifiers (PGA) 13-7.
  • the resource mapping and precoding block 21-1 receives a CSI feedback sent by the terminals based on the pilot or reference signals that were sent by the bases station during channel sounding.
  • the CSI feedback is used by the base station to beamform the data from the 96 antennas of the antenna array to the terminals that are in the domain of the base station.
  • the dynamic software controlled analog beamformer 13-4 sets the amplitude gains for all of the rest of the antenna elements for that port (i.e., for the other sub-arrays) signal to zero.
  • the AAS is configured (by appropriately setting the analog phases and gains) so that each port signal goes to its corresponding sub-array within the overall antenna array.
  • each antenna element in a sub-array receives the same signal as the other antenna elements within that sub-array, as is illustrated by Figs. 8 and 10.
  • the base station transmits a data vector s with size of L X 1, where L is the number of layers, it multiplies this vector by a digital precoder or PMI matrix, F D , with size of P X L, where P is the number of ports.
  • the PMI matrix is obtained from the UE feedback.
  • FA weights matrix
  • the analog beamformer is able to adjust the phase shift and amplitude or gain of each signal that is sent to an antenna element to thereby perform a beamforming function in the analog domain.
  • the analog weights matrix, F a is not fixed but rather represents the phase shifts and variable gains that can be applied to each signal.
  • each port signal can be sent to every antenna element of the corresponding polarization.
  • each port signal is in practice sent to only the antenna elements in the corresponding sub-array. That is, each port signal is sent to only 12 of the 48 antenna elements for that polarization. That means the gains for all of the other paths for the port signal are set to zero.
  • the ability to steer the beams generated by each sub-array within the modified 8T8R array by using the analog phase weights enables one to cover the larger scan angles that are achievable by MIMO arrays with a larger numbers of ports (e.g. a conventional 32T32R MIMO array). This is done by directing the analog generated main beams to the centers of the sub-sectors (or sub-regions) that make up the larger sector or domain.
  • the beams that can be formed by this modified 8T8R antenna system via the precoding matrices for the 8T8R MIMO system would have the patterns shown in Fig. 11. They would extend horizontally from +/- 30° for a total horizontal range of 60° and they would extend vertically from +/-5.5° for a total vertical range of 11°.
  • This domain corresponds to region 6-1 shown in Fig. 6 which represents about 1 ⁇ 4 of the maximum coverage area that is achievable by a conventional 32T32R MIMO array.
  • the analog phase shifts that are applied to each of the signals being fed to each of the 96 antenna elements in the modified 8T8R MIMO can be individually controlled, the beam patterns that are generated for those signals can be shifted. So, for example, by setting the analog phase shifts for the antenna elements during time period ti so that each sub-array generates a beam that is directed toward 30° and 5.5°, then the entire beam pattern that is achievable by the precoding matrices for the 8T8R MIMO system shifts is shown in the top row of Fig. 13. That is, the resulting beam pattern that is achievable by the precoding matrices extends horizontally from 0° to 60° and vertically from 0° to 11°.
  • the entire beam pattern that is achievable by the precoding matrices for the 8T8R MIMO is shown in the bottom row of Fig. 13. That is, the resulting beam pattern that is achievable by the precoding matrices extends horizontally from 0° to 60° and vertically from 0° to -11°. In other words, it is the same pattern as that generated in Fig. 11 but shifted by 30° and -5.5° in the f and Q directions, respectively. This angular coverage is graphically depicted in Fig. 15 as the cross-hatched pattern indicated by the legend direction 30°, -5.5°.
  • the entire beam pattern that is achievable by the precoding matrices for the 8T8R MIMO is shown in the top row of Fig. 14. That is, the resulting beam pattern that is achievable by the precoding matrices extends horizontally from 0° to -60° and vertically from 0° to 11°. In other words, it is the same pattern as that generated in Fig. 11 but shifted by -30° and +5.5° in the f and Q directions, respectively. This angular coverage is graphically depicted in Fig. 15 as the cross-hatched pattern indicated by the legend direction -30°, 5.5°.
  • the entire beam pattern that is achievable by the precoding matrices for the 8T8R MIMO is shown in the bottom row of Fig. 14. That is, the resulting beam pattern that is achievable by the precoding matrices extends horizontally from 0° to -60° and vertically from 0° to -11°. In other words, it is the same pattern as that generated in Fig. 11 but shifted by -30° and -5.5° in the f and Q directions, respectively. This angular coverage is graphically depicted in Fig. 15 as the cross- hatched pattern indicated by the legend direction -30°, -5.5°.
  • each time period has a sub- frame of duration 1 ms.
  • the total angular spread of all four time periods (ti, t 2 , t 3 , and H) summed together equals +/-6O 0 horizontally and +/-11° vertically and requires 4 sub-frames to complete the process for a total of 4 ms.
  • This is the same angular coverage as illustrated in Fig. 9 which corresponds to the 32T32R (4, 4, 8, 4) antenna system using 32 ports which is performed in one sub- frame.
  • the embodiment presented in the present application uses an 8T8R (2, 2, 8, 8) antenna system using only 8 ports and offers the same coverage area as the 32T32R (4, 4, 8, 4) antenna system.
  • the base station After collecting this information for all of the time periods that are required to cover the complete domain (i.e., four time periods in the case of the modified 8T8R MIMO system operating to meet the performance of a conventional 32T32R MIMO system), then the base station is able to identify the sub-sector and the best PMI for that sub-sector that yields the best results.
  • Fig. 16 presents a flow chart for operating a modified 8T8R MIMO active antenna array implementing the configuration depicted in Fig. 7B, to improve channel sounding capabilities and capacity. More specifically, the method is for enabling a modified 8T8R MIMO active antenna array to cover a domain that a conventional MIMO array with higher port count is capable of covering.
  • the initial steps involve determining the extent of the larger domain that can be serviced by a conventional MIMO array with a higher port count, determining the smaller size of the sub- region that can be covered by a MIMO array with a lower port count, and identifying the number and locations (i.e., the centers) of the sub-regions required to cover the entirety of the larger domain.
  • the objective is to find the number of different scans that will be needed to cover the required scan angle by using an antenna with fewer ports.
  • step 16-2 determine the maximum horizontal and vertical scan angle (or maximum angular spread) that the conventional MIMO array is capable of servicing (step 16-2). This can be determined, for example, from the appropriate codebook for the given port count and
  • the CSI-RS transmission that is used can be Class A, Class B, or a combination of the two, as previously described.
  • the base station stores the values that are fed back to it by the terminal(s), including the PMI, CQI, and RI for that time period.
  • the base station determines whether any sub-sectors that have not been sounded remain (step 16-8). If unsounded sub-sectors remain, in the next time period the base station selects the next sub-sector (step 16-9) and repeats the above-described sequence of steps. After the base station has sounded all sub-sectors, it records the analog beamformer weights for the best sub-sector and picks the best reported PMI for that sub-sector along with the reported CQI and RI (step 16-10). It then uses these values to communicate with the terminal (step 16-11).
  • the base station sets the analog weights in the active array so that each sub-array within that active array defines a main beam direction that is aimed at the center of the selected subsector. And it maps the layers to the port signals by using the precoding matrix identified by the best reported PMI.
  • the location of the terminal with which communication is being established is identified.
  • the direction of the beam that is generated by the combination of the analog and digital precoders represented by F A F D is identified (e.g. the f, Q direction along which the terminal is located) (step 18-1).
  • F A F D the direction of the beam that is generated by the combination of the analog and digital precoders represented by F A F D
  • F T an analog beamformer, for the active array system is determined.
  • F T for the active array system is determined.
  • This is the transform according to which only analog phase weights and gains are used to direct beams in that direction, f, q.
  • no beamforming precoding matrix F D is employed but rather it is, in essence, an identity matrix which might only include appropriate co- phasing parameters (step 18-2).
  • the base station applies that analog beamformer FT within the active array (step 18-3) and also uses, if required, the appropriate co-phasing parameters to map the layers to the ports (step 18-4).
  • the co-phasing parameters are used to change the phase rotation between two polarizations. In general, both polarizations have the same beam direction, but there is a phase difference between two polarizations adjusted by the co-phasing parameter.
  • the base station then sends the data (i.e., the port signals) to the terminal over beams directed towards the location of the terminal or UE (step 18-5). This is done without using any precoding matrices to perform beamforming in th digital domain.
  • the base station can improve the scan angle as described.
  • the base station can also improve the quality of the beams that are generated. More specifically, the approach represented by Fig. 17 removes unwanted sidelobes from the beam pattern.
  • Fig. 18 visually compares the results achievable by the different approaches.
  • the three columns present the beam patterns for a conventional 8T8R system, a conventional 32T32R system, and a modified 8T8R system, respectively.
  • the first and second rows present the beam patterns in a horizontal plane and vertical plane, respectively.
  • the first plot 17-1 has two spurs 17-2 and 17-3 accompanying the primary beam. This is one of the plurality of beams in the horizontal plane of the conventional 8T8R system when digital precoding methods are combined with the fixed analog beamformer method is applied to the RF chain. The resulting spurs or side-lobes distort the quality of the total beam.
  • the spurs occur because of the distance between the effective antennas of the set of twelve antennas is not uniform in both the vertical and horizontal directions. More specifically, the horizontal effective distance is 2G and the vertical effective distance is 6G. This result also occurs when employing an active array in which the main beams are directed toward the center of the relevant sub-sector.
  • the center plot 17-4 of the top row illustrates the radiation pattern for an equivalent one of the plurality of beams in the horizontal plane of the conventional 32T32R system. This beam is generated by using only conventional digital precoding methods. Note the lack of sidelobes.
  • the first plot 17-6 which corresponds to using the combination of digital precoding method with the fixed analog beamformer correction method, produces has one sidelobe 17-9 accompanying the primary beam at about -9°.
  • the sidelobes occur because the distance between the effective antennas of the set of twelve antennas is not uniform in both the vertical and horizontal directions. More specifically, the horizontal effective distance is 2G but the vertical effective distance is 6G. The vertical effective distance of 6G makes a pronounced spur 17-9. This result also occurs when employing an active array in which the main beam is directed toward the center of the relevant sub-sector.
  • the center plot 17-8 of the bottom row illustrates an equivalent one of the plurality of beams in the vertical plane of the 32T32R system.
  • This beam is generated by using only conventional digital precoding methods. Because the horizontal effective distance in the array is G while the vertical effective distance is 3G, the 32T32R antenna system generates a sidelobe 17-10.
  • Fig. 19 depicts a table that compares the performance in terms of throughput of a number of different systems (conventional vs. the modified 8T8R) for a single user (SU-MIMO) and a multi user (MU-MIMO) transmission cases when the channel is line of sight (LOS) and non-line of sight (NLOS).
  • the conventional systems includes the conventional 8T8R (2, 2, 8, 8) system and the conventional 32T32R (4, 4, 8, 4) system.
  • the modified 8T8R is compared to the conventional 32T32R (4, 4, 8, 4) system. In all cases, the last column provides the gain of the modified 8T8R system vs. the conventional 32T32R (4, 4, 8, 4) system.
  • the modified 8T8R system outperforms the conventional systems in all cases (3%, 3%, 21%, and 31%).
  • the last row shows that the modified 8T8R system demonstrates a 31% gain increase for a MU-MIMO system with 2 terminals over the conventional 32T32R (4, 4, 8, 4) system.
  • the disclosed concepts can be used with arrays of arbitrary shapes and sizes.
  • the methods described herein can be implemented by using a processor in combination with computer-readable medium that contains a program for carrying out one or more of the described steps.
  • the processor which can be implemented within the base station, can include a single machine or multiple interacting machines or processors (located at a single location or at multiple locations remote from one another).

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Abstract

L'invention concerne un procédé impliquant un système de communication MIMO comprenant une antenne réseau à commande de phase pour établir une communication avec un terminal situé dans un domaine, le procédé consistant : à définir une pluralité de sous-domaines à l'intérieur du domaine ; pour chaque sous-domaine, à définir un ensemble correspondant de pondérations de phases analogiques à appliquer à l'antenne réseau à commande de phase pour diriger des faisceaux vers ce sous-domaine ; à sélectionner successivement chaque sous-domaine parmi la pluralité de sous-domaines et pour chaque sous-domaine sélectionné : (a) appliquer l'ensemble de pondérations de phases analogiques pour ce sous-domaine sélectionné à l'antenne réseau à commande de phase ; (b) effectuer un sondage de canal avec le terminal tandis que le sous-domaine est sélectionné ; et (c) recevoir une rétroaction en provenance du terminal pour ce sous-domaine sélectionné ; et après la sélection de tous les sous-domaines et à partir de la rétroaction reçue, identifier un meilleur sous-domaine et identifier une meilleure matrice de précodage qui, en combinaison avec le meilleur sous-domaine, fournit un meilleur canal de communication pour le terminal.
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